Controlling the spatial deposition of electrospun fibre

Abdul Hamid, Nurfaizey

January 2014

Electrospinning process is a simple and widely used method for producing polymeric nanofibres. However, despite its popularity, significant challenges remain in controlling the fibre deposition due to the complex nature of electrospinning process. The process is renowned for its chaotic motion of fibre deposition, also known as the whipping instability. This instability is caused by electrostatic and fluid dynamics interactions of the charged jet and it is partly responsible for the thinning of the fibres into nanoscale diameters. Due to the instability, an electrospinning process typically deposits random orientated fibres in a circular deposition area. Furthermore, there is no control over the location where the fibres land on the collector electrode except that the fibres always travel through the shortest trajectory between the source and the collector electrodes. In this study, an alternative controlled deposition technique was proposed based on electric field manipulation (EFM). The main hypothesis of this study is that a consistent and repeatable method of controlled deposition can be achieved by using EFM. EFM was achieved by introducing a pair of charged auxiliary electrodes positioned adjacent and perpendicular to the fibre deposition direction. The applied voltage of either direct current (dc) or time-varying (ac) voltage at the auxiliary electrodes act as control to influence the spatial location and size of the deposition area. Samples were produced on black paper substrates and scanned into greyscale images. An image analysis technique was developed to measure the shift and size of the deposition area. A computer simulation was used to calculate the electric field strength and to simulate the behaviour of fibre response based on the trajectory of a charged particle. An image analysis based on greyscale intensity measurement was also developed to examine the uniformity of the deposition area. Finally, fibre characterisation was carried out to examine the fibre morphology, diameter, and orientation based on scanning electron micrographs. The results from this study showed that EFM can provide a consistent and repeatable control of the deposition area. When the auxiliary electrodes were independently charged with two dc voltages, it was observed that the deposition area moved away from the most positive electrode. The magnitude of shift of the deposition area was found to increase linearly with voltage difference between the auxiliary electrodes. Furthermore, the aspect ratio of the deposition area (ratio of width over height) decreased linearly with base voltage i.e. lower of the two auxiliary electrode voltages. These two controls were found to act independently from each other and can be described as two separate controls i.e. voltage difference for spatial location and base voltage for aspect ratio of the deposition area. A similar response was observed in simulation i.e. the particle moved away from the most positive electrode. Simulation results also showed that the x-axis component of the electric field (Ex) was responsible for the shift in location and the reduction of aspect ratio of the deposition area. When the auxiliary electrodes were charged with two antiphase time-varying voltages, continuous scanning of the electrospinning jet was observed producing a wide electrospun fibre mat. It was first thought the smooth oscillation of a sine wave would produce a more uniform deposition pattern compared to a triangle wave, but the results showed otherwise. The inferior uniformity of the sine wave sample was found due to the variability of the jet scanning speed when compared to the constant speed achieved when using a triangle wave. It was also observed that the deposition pattern can be further improved by using two clipped triangle wave voltages. The results open up the possibility for further exploiting the control voltage to achieve the desired deposition pattern. Two case studies were presented to demonstrate the applicability of the technique in real electrospinning applications. In the first case study, it was demonstrated that the continuous scanning of electrospinning jet was capable of eliminating the stripe deposition pattern which is commonly associated to a multi-spinneret electrospinning system. In the second case study, it was found that the alignment and distribution of aligned fibres in a gap electrospinning system can be improved by using the EFM technique. A new technique was also introduced to produce a multi-layer orientated fibre construct. These application examples showed that the EFM technique is ready for the production of engineered electrospun fibre constructs. This would extend the use of electrospun fibres to applications which is currently limited by geometrical constraints of the fibre constructs.

Electrospinning

nanofiber

electrospun fiber

controlled deposition

aligned fiber

Dépôt contrôlé de nanoparticules magnétiques par électrospray et nanodispending / Controlled deposition of magnetic nanoparticles by electrospray nanodispending

Agostini, Pierre

05 December 2014

Les nanoparticules (NP) magnétiques ont potentiellement de nombreux débouchés technologiques notamment en oncologie, dans la confection d’aimants permanents ou pour le stockage informatique à très haute densité. Cependant, leurs propriétés magnétiques sont aujourd’hui mal connues car les techniques de caractérisation existantes ne sont pas assez performantes. Une technique prometteuse offrant la possibilité de mesurer précisément les propriétés magnétiques d’une NP unique est le résonateur mécanique à nanotube de carbone (RMNC). L’enjeu de ma thèse a été de développer une technique pour déposer une NP magnétique unique sur un RMNC. Nous avons menés en parallèle l’étude de deux techniques, le NAnoscale DIspensing System (NADIS®) et l’électrospray. Les différentes expériences menées m’ont permis de contrôler le dépôt de NP unique de polystyrène avec NADIS et de NP uniques de Fe et FeCo d’une dizaine de nanomètre avec l’électrospray sur une surface vierge. Ceci m’a permis de valider la faisabilité de déposer une NP unique sur un RMNC. / Magnetic nanoparticles have potentially many technology opportunities including oncology, manufacture of permanent magnets or computer storage at very high density. However, their magnetics properties are not well known today because the existing characterization techniques are not enough efficient. A promising technique offering the ability to accurately measure the magnetic properties of a single NP is the carbon nanotube mechanical resonator (CNMR). The challenge of my PhD has been to develop a technique for depositing a single magnetic NP on CNMR. We study two techniques in parallel, Nanoscale Dispensing System (NADIS®) and electrospray. The different experiences led have allowed me to control the deposition of a single polystyrene NP with NADIS and unique Fe and FeCo NP of ten nanometers with electrospray onto a free surface. This allowed me to validate the feasibility of depositing a single NP on a CNMR.

Nanoparticules

Magnétisme

Dépôt contrôlé

Électrospray

NADIS

Nanoparticles

Magnetism

Controlled deposition

Electrospray

NADIS

540

Controlled deposition and alignment of electrospun PMMA-g-PDMS nanofibers by novel electrospinning setups / Kontrollerad beläggning och linjering av elektrospunna PMMA-g-PDMS nanofibrer genom en ny elektrospinningsmetod

Haseeb, Bashar

January 2011

Electrospinning is a useful technique that can generate micro- and nano-meter sized fibers from polymer materials. Modification of the electrospinning parameters and apparatus can generate nanofibers for use in diverse applications ranging from tissue engineering to nanocomposite fabrication; however, electrospun fibers are typically collected in a random orientation and over large areas limiting their applications.  Here we present several methods to control the deposition of electrospun nanofibers, such as the use of a single auxiliary electrode ring and a negatively charged collector substrate to control the deposition area and the construction of a parallel electrode collector known as the triple electrode setup to control the uniaxial alignment of nanofibers. The numerous constructed setups were advanced by the use of electric field computations to assess the distribution of the electric field and its effect on the deposition behavior and morphology of the electrospun nanofibers. The electrostatic force imposed by the auxiliary electrodes provides converged electric fields that direct the nanofibers to their desired deposition targets. Here it is shown that the use of the auxiliary electrode ring dramatically decreased the deposition area of nanofibers, the negatively charged substrate yielded more uniform nanofibers and the triple electrode setup is a viable method to achieve uniaxially aligned nanofiber mats.    The electrospinning of copolymers appears as an attractive option for enhancing the overall properties of nanofibers as it offers possibility of an intrinsic control of the polymeric material itself. The poly(methyl methacrylate)-graft-poly(dimethylsiloxane) graft copolymer  (PMMA-g-PDMS) is considered to be an organic-inorganic hybrid material with much potential in its use in nanocomposites, and in this work has been successfully synthesized and electrospun via the various constructed electrospinning setups.   In the final elements of this work, the triple electrode setup is used in combination with a dynamic rotating collector to yield a novel collector and has been successfully used to produce PMMA-g-PDMS nanofiber sheets that were further incorporated in a PDMS matrix to yield nanocomposite sheets. A variant of the triple electrode setup with partially insulated electrodes is devised in combination with a methodology to remove the nanofibers from the collector. The nanofibers once removed and dried were incorporated in a PDMS matrix to yield nanocomposites. The preferential dissolution of the fibers from the matrix rendered the fibers to templates and a final porous material with uniaxial nanochannels could be obtained.   This work is believed to be able to lead to a better understanding of the mechanisms of nanofiber deposition and alignment, and should be of help to the design of more practical collecting structures, hence promoting the applications of the electrospinning technique.

Electrospinning

nanofibers

nanofiber alignment

PMMA-g-PDMS

controlled deposition

triple electrode.